Barrier device with fluid bypass for multi-zone wellbores

ABSTRACT

In one aspect, a device for use in a wellbore includes a tubular body; a barrier member associated with an outer surface of the tubular body configured to retain a proppant; an actuating member associated with the barrier member configured to expand the barrier member in an annular direction; and a fluid channel associated with an upper extent and a lower extent of the barrier member, configured to allow a fluid flow therethrough. In another aspect, a method for completing a multi-zone wellbore, includes deploying a barrier device at a downhole location within the wellbore; expanding a barrier member in an annulus of the wellbore; providing proppant in the annulus of the wellbore; retaining the proppant in the annulus via the barrier member; and providing a fluid flow between an upper extent and a lower extent of the barrier member.

BACKGROUND

1. Field of the Disclosure

This disclosure relates generally to barrier devices to facilitateaccumulation of proppant and a fluid flow therethrough.

2. Background

Wellbores are drilled in subsurface formations for the production ofhydrocarbons (oil and gas). Hydrocarbons are trapped in various traps orzones in the subsurface formations at different depths. Such zones arereferred to as reservoirs or hydrocarbon-bearing formations orproduction zones. In production zones, it is often desired to performcompletion operations such as fracing, frac packing, or gravel packingoperations to stabilize the wellbore and facilitate production withinthe production zones. When there is a great distance between zones suchcompletion operations often require a large amount of proppant, such assand, gravel or other materials. In a multi-zone well bore, it is oftendesired to minimize the amount of proppant required for completionoperations.

The disclosure herein provides a barrier device to minimize the amountof proppant required for completion operations by facilitatingaccumulation of proppant and a fluid flow therethrough.

SUMMARY

In one aspect, a device for use in a wellbore includes a tubular body; abarrier member associated with an outer surface of the tubular bodyconfigured to retain a proppant; an actuating member associated with thebarrier member configured to expand the barrier member in an annulardirection; and a fluid channel associated with an upper extent and alower extent of the barrier member, configured to allow a fluid flowtherethrough.

In another aspect, a system for use in a wellbore includes a tubingstring; a service tool configured to provide a proppant in an annulusaround the tubing string; and a barrier device including a tubular bodyassociated with the tubing string; a barrier member associated with anouter surface of the tubular body configured to retain the proppant; anactuating member associated with the barrier member configured to expandthe barrier member in the annulus; and a fluid channel associated withan upper extent and a lower extent of the barrier member, configured toallow a fluid flow therethrough.

In another aspect, a method for completing a multi-zone wellboreincludes deploying a barrier device at a downhole location within thewellbore; expanding a barrier member of the barrier device in an annulusof the wellbore; providing proppant in the annulus of the wellbore;retaining the proppant in the annulus via the barrier member; andproviding a fluid flow between an upper extent and a lower extent of thebarrier member.

Examples of the more important features of certain embodiments andmethods have been summarized rather broadly in order that the detaileddescription thereof that follows may be better understood, and in orderthat the contributions to the art may be appreciated. There are, ofcourse, additional features that will be described hereinafter and whichwill form the subject of the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

For a detailed understanding of the apparatus and methods disclosedherein, reference should be made to the accompanying drawings and thedetailed description thereof, wherein like elements are generally givensame numerals and wherein:

FIG. 1 shows an exemplary wellbore system that includes a barrierdevice, according to one non-limiting embodiment of the disclosure;

FIG. 2A shows a partial cross-section about centerline ‘C’ of anon-limiting embodiment of a barrier device for use in wellbore system,including the wellbore system shown in FIG. 1, for deployment in awellbore, such as wellbore shown in FIG. 1;

FIG. 2B shows a partial cross-section about centerline ‘C’ of thebarrier device of FIG. 2A with the barrier member in an expandedposition; and

FIG. 2C shows a partial cross-section about centerline ‘C’ of the fluidchannel of the barrier device of FIG. 2A.

DETAILED DESCRIPTION OF THE DRAWINGS

FIG. 1 is a line diagram of a wellbore system 100 that may be used forcompletion operations in a formation 104 with multiple production zonesZ1, Z2, etc. In an exemplary embodiment, the system 100 includes acasing 108 cemented in wellbore 102 formed in a formation 104. In analternative embodiment, wellbore 102 is provided in an open hole withoutcasing 108. Tubing 110 is deployed within wellbore 102 to a downholelocation 106.

Tubing 110 may extend to multiple zones Z1, Z2, etc within wellbore 102.Each zone, such as zone Z1, may be isolated within wellbore 102 andannulus 134 by packers 118, 120. An isolation packer 120 isolates zoneZ1 from lower zones, such as zone Z2 and other portions of formation104. Top packer 118 similarly isolates zone Z1 from zones above Z1 andother portions of formation 104.

During completion operations, a crossover tool 122 may be introducedinto the wellbore 102. Crossover tool 122 is deployed within tubingstring 110 to a downhole location 106. Crossover tool 122 introducesproppant flow 126 into an isolated zone, such as zone Z1, to stabilizethe wellbore 102 and stimulate production of formation fluids 130.Proppant may include sand, gravel, and other completion materials tofacilitate fracing, frac packing, and gravel packing operations.Proppant flow 126 crosses over into annulus 134 via a frac sleeve 124 oftubing string 110. Such proppant flow 126 is provided under pressureinto the annulus 134 to fill the isolated zone Z1. Proppant flow 126accumulates as packed material 128 (gravel pack) and enters formation104.

Casing 108 has perforations 114 to allow proppant flow 126 intoformation 104. As packed material 128 accumulates, proppant flow 126flows through perforations 114 of casing 108. Proppant flows along apreferred plane to interface with formation 104. Fractures 132 information 104 may be created, expanded, or structurally supported by theflowed proppant 126. Proppant flow 126 may include materials ofdifferent sizes and densities to create, expand and support fractures132 within formation 104. Such fractures 132 facilitate and enhance theproduction of formation fluids 130 such as oil and gas.

Completion operations may continue until the production zone Z1 is fullytreated. A zone is considered treated when packed material 128 hasinteracted with the of zone Z1 up to the well screen 112 that willreceive formation fluid flow 130. When the well screen 112 has beencovered by packed material 128, a rise in pressure indicates to theoperator a “screen out” condition is achieved, signaling the completionoperation has finished. After completion operations a sliding sleeve 116may be opened to allow flow of formation fluid 130 into tubing string110. A well screen 112 prevents proppant and other solids from enteringtubing string 110.

Conventionally, proppant flow 126 must flow the entire length ofisolated zone Z1 and accumulate as packed material 128 above isolationpacker 120 to accumulate and create a desired “screen out” condition. Ifthere is a great distance between zones (such as thousands of feet), alarge amount of proppant must be used. To reduce the amount of proppantused to complete a zone, wellbore system 100 includes barrier device140. Barrier device 140 is disposed immediately down hole of zone Z1 andallows packed material 128 to accumulate directly below zone Z1 whileallowing fluid flow therethrough to maintain a neutral pressuredifferential. Accordingly, less proppant flow 126 is required to achievea “screen out” condition.

A non-limiting embodiment of the barrier device for use in the wellboresystem 100 is described in reference to FIGS. 2A-2C.

FIG. 2A shows a partial cross-section about centerline ‘C’ of anon-limiting embodiment of a barrier device for use in wellbore system,including the wellbore system shown in FIG. 1, for deployment in awellbore, such as wellbore shown in FIG. 1. Barrier device 240 includestubular body 242, an actuator body 266, and a barrier member 258.

Tubular body 242 of barrier device 240 is associated with tubing string110. In an exemplary embodiment, tubular body 242 is threadedly coupledwith tubing string 110. Barrier device 240 may be coupled inline withtubing string 110. Tubular body 242 has an inner diameter that allows aflow therethough, such as flow 130 (FIG. 1) of formation fluids.Actuator body 266 and barrier member 258 are generally disposed on theouter surface of tubular body 242.

Actuator body 266 is disposed on the outer surface of tubular body 242and is configured to expand barrier member 258. In an exemplaryembodiment, actuator body 266 utilizes pressure received from withintubular body 242 and tubing string 110. In other embodiments, actuatorbody 266 is actuated by mechanical means or any other suitable means.

In an exemplary embodiment, piston 244 is associated with actuator body266. Piston area 246 of piston 244 is in fluid communication with apressure within tubular body 242 and tubing string 110. A port 252directs fluid pressure to a piston area 246. Fluid pressure urges pistonarea 246 and piston 244 generally downward along on the outside surfaceof tubular body 242, while an upper seal 248 and a lower seal 250contain fluid pressure within piston area 246.

In an exemplary embodiment, actuator body 266 is fixed or retained untila desired pressure or force applied. Selectively retaining actuator body266 allows for barrier device 240 to be run into wellbore 102 withoutdeploying barrier member 258 or otherwise deploying barrier member 258unintentionally. Shear screw 262 is associated with piston 244 torestrict movement of piston 244 and actuator body 266 until a determinedforce is applied. When such a determined force is applied, the shearscrew 262 is sheared and the piston 244 may move downwardly. In otherembodiments, actuator body 266 is selectively retained by other suitablemeans.

Barrier member 258 is configured to accumulate proppant and preventproppant from passing therethrough. Barrier member 258 may be aresilient material or an elastomeric material, including polymer andrubber. The use of a resilient material for barrier member 258 furtherallows the barrier device 240 to easily be retrieved. If the barrierdevice 240 is prematurely set, a straight pull to the barrier device 240will strip material off the barrier member 258 allowing retrieval fromthe wellbore 102.

In other embodiments, barrier member 258 is a screen or mesh typematerial to allow fluid flow therethrough while retaining proppant.

FIG. 2B shows a partial cross-section about centerline ‘C’ of thebarrier device of FIG. 2A with the barrier member 258 in an expandedposition. In an exemplary embodiment, actuator body 266 moves downwardlyto compress barrier member 258 against a fixed bottom sub 260. As aresult of this compression in a longitudinal direction barrier member258 expands annularly outward. In an exemplary embodiment barrier member258 expands toward wellbore 102 or casing 108 to form a sealingrelationship.

In an exemplary embodiment, locking member 264 retains actuator body 266in a lowered position, to allow barrier member 258 to remain in anexpanded state. Locking member 264 may use any suitable means to lockactuator body 266 in a downward position. In an exemplary embodiment,locking member 264 is a ratchet locking mechanism that allows actuatorbody 266 to move downwardly in one direction, by allowing teeth of sucha mechanism to move downwardly, but resists the movement of the actuatorbody 266 in an opposite upward direction. Such a locking member 264 maybe desirable when actuator body 266 is actuated by fluid pressure. Whenpressure is relieved, locking mechanism 264 may retain the piston in adownward state, allowing retention of the expanded state of barriermember 258.

FIG. 2C shows a partial cross-section about centerline ‘C’ of the fluidchannel of the barrier device of FIG. 2A. When barrier member 258 isdeployed, fluid flow 272 may be restricted therethough. Duringcompletion operations, it is desirable to maintain neutral pressure orotherwise prevent the accumulation of pressure within the productionzone. Fluid channel 268 allows fluid flow 272 to pass from an upperextent of barrier member 258 to a lower extent of barrier member 258when barrier member 258 is deployed. Fluid flow 272 enters above barriermember 258 at upper channel opening 254. Fluid flow 272 continues beyondbarrier member 258 to exit via lower channel opening 256. Fluid flow 272may flow in an opposite direction to achieve neutral pressure orotherwise freely transfer pressure within the zone. Advantageously,maintaining a neutral pressure environment allows for packers to be setdownhole if required. In an exemplary embodiment, fluid channel 268 isdisposed between barrier member 258 and tubular body 242. In certainembodiments a screen 270 may be disposed between fluid channel 268 andbarrier member 258 to allow an adequate separation and a flow paththerethrough. In certain embodiments, the fluid channel 268 is formedfrom a coarse thread, or an otherwise rough or uneven surface to allowflow therethrough. In an alternative embodiment, fluid channel 268 isdisposed within barrier member 258. In certain embodiments, barriermember 258 selectively allows a fluid flow 272 therethrough without theuse of a dedicated fluid channel 268.

Advantageously, the use of barrier device 240 allows for less proppantto be used, while still allowing for wellbore integrity. Less proppantis used in multi-zone completions, and particularly, less proppant isused in multi-zone completions where a great distance separatesproduction zones. Accordingly, less wear on service equipment, such ascrossover tool 122, is experienced. Further, since less proppant isrequired, completion operations can be completed faster compared toconventional methods. Additionally, due to the configuration of thebarrier device 240, barrier device 240 can be produced for a relativelylow cost.

Therefore in one aspect, the present disclosure provides a device foruse in a wellbore includes a tubular body; a barrier member associatedwith an outer surface of the tubular body configured to retain aproppant; an actuating member associated with the barrier memberconfigured to expand the barrier member in an annular direction; and afluid channel associated with an upper extent and a lower extent of thebarrier member, configured to allow a fluid flow therethrough. Incertain embodiments, the actuating member including a piston in fluidcommunication with a tubular pressure associated with the tubular body.In certain embodiments, the actuating member including a locking memberconfigured to retain a position of the actuating member. In certainembodiments, the actuating member including a biasing member configuredto retain an initial position of the actuating member up to apredetermined force. In certain embodiments the fluid channel isdisposed within the barrier member. In certain embodiments, the fluidchannel is disposed between the outer surface of the tubular body andthe barrier body.

In another aspect, the present disclosure provides a system for use in awellbore includes a tubing string; a service tool configured to providea proppant in an annulus around the tubing string; and a barrier deviceincluding a tubular body associated with the tubing string; a barriermember associated with an outer surface of the tubular body configuredto retain the proppant; an actuating member associated with the barriermember configured to expand the barrier member in the annulus; and afluid channel associated with an upper extent and a lower extent of thebarrier member, configured to allow a fluid flow therethrough. Incertain embodiments, the actuating member including a piston in fluidcommunication with a tubular pressure associated with the tubular body.In certain embodiments, the actuating member including a locking memberconfigured to retain a position of the actuating member. In certainembodiments, the actuating member including a biasing member configuredto retain an initial position of the actuating member up to apredetermined force. In certain embodiments the fluid channel isdisposed within the barrier member. In certain embodiments, the fluidchannel is disposed between the outer surface of the tubular body andthe barrier body. In certain embodiments, the barrier device is disposedimmediately downhole of a production zone. In certain embodiments, thebarrier device is disposed above a second downhole production zone.

In another aspect, the present disclosure provides a method forcompleting a multi-zone wellbore, includes deploying a barrier device ata downhole location within the wellbore; expanding a barrier member ofthe barrier device in an annulus of the wellbore; providing proppant inthe annulus of the wellbore; retaining the proppant in the annulus viathe barrier member; and providing a fluid flow between an upper extentand a lower extent of the barrier member. In certain embodiments,further including deploying the barrier device immediately downhole of aproduction zone. In certain embodiments, further including deploying thebarrier device above a second downhole production zone. In certainembodiments, further including providing a tubular pressure to a pistonassociated with the barrier member. In certain embodiments furtherincluding resisting an expansion of the barrier member until apredetermined force is applied to the piston. In certain embodiments,further including retaining an expansion of the barrier member.

1. A device for use in a wellbore, comprising: a tubular body; a barriermember associated with an outer surface of the tubular body configuredto retain a proppant; an actuating member associated with the barriermember configured to expand the barrier member in an annular direction;and a fluid channel associated with an upper extent and a lower extentof the barrier member, configured to allow a fluid flow therethrough. 2.The device of claim 1, the actuating member including a piston in fluidcommunication with a tubular pressure associated with the tubular body.3. The device of claim 1, the actuating member including a lockingmember configured to retain a position of the actuating member.
 4. Thedevice of claim 1, the actuating member including a biasing memberconfigured to retain an initial position of the actuating member up to apredetermined force.
 5. The device of claim 1, wherein the fluid channelis disposed within the barrier member.
 6. The device of claim 1, whereinthe fluid channel is disposed between the outer surface of the tubularbody and the barrier body.
 7. A system for use in a wellbore,comprising: a tubing string; a service tool configured to provide aproppant in an annulus around the tubing string; and a barrier devicecomprising: a tubular body associated with the tubing string; a barriermember associated with an outer surface of the tubular body configuredto retain the proppant; an actuating member associated with the barriermember configured to expand the barrier member in the annulus; and afluid channel associated with an upper extent and a lower extent of thebarrier member, configured to allow a fluid flow therethrough.
 8. Thesystem of claim 7, the actuating member including a piston in fluidcommunication with a tubular pressure associated with the tubular body.9. The system of claim 7, the actuating member including a lockingmember configured to retain a position of the actuating member.
 10. Thesystem of claim 7, the actuating member including a biasing memberconfigured to retain an initial position of the actuating member up to apredetermined force.
 11. The system of claim 7, wherein the fluidchannel is disposed within the barrier member.
 12. The system of claim7, wherein the fluid channel is disposed between the outer surface ofthe tubular body and the barrier member.
 13. The system of claim 7,wherein the barrier device is disposed immediately downhole of aninitial production zone.
 14. The system of claim 13, wherein the barrierdevice is disposed above a downhole production zone disposed below theinitial production zone.
 15. A method for completing a multi-zonewellbore, comprising: deploying a barrier device at a downhole locationwithin the wellbore; expanding a barrier member of the barrier device inan annulus of the wellbore; providing proppant in the annulus of thewellbore; retaining the proppant in the annulus via the barrier member;and providing a fluid flow between an upper extent and a lower extent ofthe barrier member.
 16. The method of claim 15, further comprisingdeploying the barrier device immediately downhole of an initialproduction zone.
 17. The method of claim 16, further comprisingdeploying the barrier device above a downhole production zone disposedbelow the initial production zone.
 18. The method of claim 15, furthercomprising providing a tubular pressure to a piston associated with thebarrier member.
 19. The method of claim 18, further comprising resistingan expansion of the barrier member until a predetermined force isapplied to the piston.
 20. The method of claim 15, further comprisingretaining an expansion of the barrier member.